cargo securing – comparison of different quality roads · 1016 martin vlkovský, petr veselík...
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ACTA UNIVERSITATIS AGRICULTURAE ET SILVICULTURAE MENDELIANAE BRUNENSIS
Volume 67 88 Number 4, 2019
CARGO SECURING – COMPARISON OF DIFFERENT QUALITY ROADS
Martin Vlkovský1, Petr Veselík2
1�Department�of�Logistics,�Faculty�of�Military�Leadership,�University�of�Defence�in�Brno,�Kounicova�65,�662 10 Brno,�Czech Republic
2�Department�of�Quantitative�Methods,�Faculty�of�Military�Leadership,�University�of�Defence�in�Brno,�Kounicova 65,�662 10 Brno, Czech Republic
To�link�to�this�article: https: / / doi.org / 10.11118 / actaun201967041015Received: 10.�4.�2019, Accepted: 26.�6.�2019
To�cite�this�article: VLKOVSKÝ MARTIN,�VESELÍK�PETR.�2019.�Cargo�Securing – Comparison�of�Different�Quality�Roads.� Acta Universitatis Agriculturae et Silviculturae Mendelianae Brunensis,�67(4): 1015 – 1023.
Abstract The�article�deals�with�the subject�of�the impact�which�road�surfaces�have�onto�cargo�and�the securing�of� cargo� against� shocks� during� road� transport.� The applicability� of� the key� EN� 12191‑1:2010�standard�is�discussed,�not�only�for�common�conditions,�but�also�for�specific�transport�conditions�on�low‑quality�road�surfaces.�Part�of�the article�involves�carrying�out�a transport�experiment�on�a road�paved�with�granite�blocks�and�on�a highway,� from�which�data�on� the impact�of�shocks�on�cargo�(acceleration�coefficients�values)�were�obtained.�The data�were�statistically�evaluated�and�compared�to� the normatively� determined� values� of� these� acceleration� coefficients.� A parametric� statistical�analysis� (two‑sample� t‑test)�was�used� to� compare� the values�of� the acceleration�coefficients� from�the two�types�of�surfaces.�The analysis�conducted�shows�statistically�significant�differences�between�the data�measured�on� the road�paved�with�granite�blocks�and�on� the highway.�Using�correlation�analysis,� the dependence�of� the acceleration�coefficient�values�and� inertial� forces�affecting� cargo�during�transport�were�verified.�For�the relevant�axes�(x – longitudinal�and�y – transverse),�a very�strong�correlation�was�found.�
Keywords:� transport,� cargo� securing,� acceleration� coefficient,� inertial� force,� parametric�methods,�two‑sample�t‑test�
INTRODUCTION
Although�cargo�securing�in�road�freight�vehicles�is� not� a new� issue,� a number� of� shortcomings�occurs�in�this�area.�The main�shortcomings�include�above�all� the link�with� road� traffic�accident� rates,�or�the event�of�traffic�accidents�caused�by�incorrect�or�insufficient�cargo�securing.�Within�the European�Union, it is estimated that up to 25% of all accidents
caused by truck drivers are caused by improper cargo�securing�(EC�DGET,�2014).�The� Automotive� Manufacturers� and� Importers�
Association�(APIA)�in�cooperation�with�the ČESMAD�Bohemia� association� organized� a conference�where� other� alarming� numbers� were� heard.�Every� third� day,� a truck� accident� occurs� due� to�an� inappropriate� cargo� securing� in� the Czech�Republic� (CR).� Traffic� accidents,� however,� can�only� be� considered� as� the tip� of� the iceberg,� as� it�
1016 Martin Vlkovský, Petr Veselík
was found during inspections on Czech roads that almost half of all cargo was not secured properly (SISA / ČESMAD�BOHEMIA,�2018).�The� DEKRA� company� reports� an� analogous�
number,�although�only� in� the segment�of�vehicles�over� 12 t� (DEKRA,� 2016).� A shortcoming� in�the statistics� is� the monitoring� of� the technical�causes� of� traffic� accidents� with� different� internal�classifications.� In� 2017� the “improper� stowage�of� cargo”� caused� almost� 30%� of� accidents�caused� by� technical� defects� in� the CR� (POLICE�OF� THE CR,� 2018).� The overloading� of� trucks� is�a related�problem,�where,� according� to�data� from�the Road�Transport�Services�Centre�established�by�the Ministry� of� Transport� of� the Czech� Republic,�almost�half�of�the vehicles�were�overloaded�during�weight�checks�(ROAD�TRANSPORT�CENTER,�2014).Shortcomings� in� the area�of� cargo� securing� can�
be divided into:• Deliberate: primarily�for�economic�reasons,�such�as�overloading�vehicles,�choosing�an insufficient�number of fastening devices, or using old and damaged�fasteners.�
• Caused�by�negligence: primarily�due� to� the lack�of� knowledge� of� the relevant� regulations� and�requirements� on� fastening� the cargo,� including�the choice�of�suitable�fasteners.�
• Unintentional: that� is,� when� the worker�responsible� for� loading� the cargo� distributes�the fasteners� in� good� faith� in� accordance� with�the known�regulations�and�requirements.�
Based� on� the list� above,� it� can� be� stated� that�the first� two� problems� are� primarily� those� of�management – motivation� and� supervision� over�subordinates’�activities.�The last�problem�is�instead�a transport‑technical� one,� where� for� the purpose�of correct cargo securing, it is necessary to know� the parameters� of� transportation� before�securing� is� deployed.� Such� parameters� include�knowing� the (assumed)�magnitude� of� the inertial�forces� affecting� cargo� during� transport.� These�can be determined using normative values of acceleration� coefficients� on� individual� axes� (x, y and z),� however� this� is� a theoretical� assumption�based�on�empirical�studies�carried�out� in� the past�when�the parameters�of�the transport�system�were�different� (e.g.� vehicles,� road� surfaces).� A more�laborious� and� time‑consuming� procedure� is�the experimental�detection�of�shocks�(acceleration�coefficient� values)� during� transport� under� similar�conditions�using�data�loggers.�Such�measurements,�ceteris paribus,� assist� in� choosing� the appropriate�load‑securing� methods� for� transportation� under�similar�conditions.�
Such�an�experimental�approach�is�of�importance�in cases where realistically measured shocks (magnitude� of� the acceleration� coefficients)�do� not� correspond� with� the normative� values�of� the acceleration� coefficients� according� to�EN 12195‑1:2010�(EN�12195‑1:2010).�The� article� further� focuses� on� the last�
area: unintentional� non‑compliance� with�the requirements�of�cargo�securing.�In�such�cases,�an� improvement� in� the human� management�system� would� not� result� in� the desired� effect�because� the problem� is� the absence� of� relevant�data that is necessary either for software processing of� the cargo� securing� plan,� or� for� a manual�solution.� On� the basis� of� pre‑research,� significant�deviations� were� found,� especially� under� specific�conditions – on� low‑quality�roads� (Vlkovský et al., 2017;� Vlkovský et al.,� 2018).� In� connection� with�the accident� rate,� it� is� also� possible� to� quantify�the impact� of� improper� or� insufficient� cargo�securing� economically� in� the form� of� social� loss�caused�by�death�or�injury�to�persons�and�property�losses�(Vlkovský,�Veselík�and�Grzesica,�2018).�These�impacts�may�be�significantly�greater�during�
the transport� of� dangerous� goods.� In� such� cases,�it� is� not� possible� to� speak� of� a higher� likelihood�of an accident, but of higher impact on persons, technology,�infrastructure,�and�the environment.�In�the context�of�the above,�the likelihood�of�a traffic�accident�will� be� higher� on� low‑quality� roads� (see�Risk�Matrix�in�Fig. 1).The�transport�of�dangerous�goods�on�low‑quality�
roads� is� carried� out� by,� for� example,� the military�(ammunition,� fuel,� etc.)� or� farmers� (pesticides,�disinfecting chemicals, diesel, pressure cylinders, etc.),�(Walter,�2018).�Fig. 1� shows� that� the transport� of� dangerous�
goods� on� low‑quality� roads�would,�without� other�measures,�appear�in�the red�part�of�the risk�matrix�(signifying�“intolerable”).�The impact�of�dangerous�goods on persons, technology, infrastructure and the environment�in�a case�of�a traffic�accident�can�be�mitigated�by�complying�with� the requirements�of� the European� Agreement� on� the International�Carriage� of� Dangerous� Goods� by� Road� (ADR,�2017).� Such� experiments� include� a requirement�on�a vehicle’s� technical� condition� that� can� reduce�the likelihood�of�a road�accident.�During�transport�on� low‑quality�roads,� it�can�be�assumed�that�with�a greater� impact� of� shocks� onto� a vehicle� and�cargo� (Grzesica,� 2018),� the likelihood� of� a traffic�accident� increases�hypothetically.�This�risk�will�be�all�the greater�if�the input�parameters�for�choosing�the securing� method� do� not� correspond� with�the given� type� of� a transport� route.� The values�
� Cargo�Securing�–�Comparison�of�Different�Quality�Roads� 1017
of� the acceleration� coefficients� defined� in� EN�12195:1‑2010� (EN� 12195:1‑2010)� are� intended�for use on common roads although there may be differences – see�e.g.�(Vlkovský�and�Rak,�2017).The�issue�of�freight�transport�is�the area�of�road�
transport,�which�is�based�on�a wide�range�of�general�regulations,� as� well� as� specific� manuals� covering�the transport�of�specific�commodities.�In�accordance with�the standard�EN�12195‑1:2010�(EN 12195‑1:2010), EN� 12195‑2:2000� (EN 12195‑2:2000)� is� used�for� the tested� method� of� fastening� with� the aid�of� fastening� straps.� For� correct� fastening� it� is�necessary�to�know�the capacity�of�the load‑bearing�anchoring� points,� which� is� covered� by� EN�12640:2000�(EN�12640:2000),�and�the construction�of�the trucks�or�semi‑trailers�and�trailers�according�to� EN� 12642:2001� (EN� 12642:2001).� Instructions�of� the Association� of� German� Engineers� VDI�2700:2009�(VDI�2700:2009)�are�applicable�too.�
The principles of proper cargo securing are further elaborated by other multinational institutions,� in� particular� the European Best Practice Guidelines on Cargo Securing for Road Transport� (UNECE,� 2014)� or� the IMO / ILO / UNECE Code of Practice for Packing of Cargo Transport Units� (CTU� Code,� 2014),� or� focused� on� dangerous�goods – European Agreement Concerning the International Carriage of Dangerous Goods by Road� (ADR,� 2017),� or� for� abnormal� goods – Road Safety: Best Practice Guidelines on Cargo Securing and Abnormal Transport� (EC� DGET,� 2016).� These�standards, manuals and documents are further elaborated� by� specific� multinational� companies,�reflecting� the transport� of� commodities� that� are�the subject�of�their�businesses.�Several�monographs�are� dedicated� to� the issue� of� cargo� securing.� It� is�worth�mentioning�T.�Lerher’s�book�Cargo Securing in Road Transport Using Restraining Method with Top‑Over Lashing,� where� the author� discusses�some general rules of road cargo securing with
particular�focus�on�top‑over�lashing�(Lerher,�2015).�The monograph�of�T.�Lerher�builds�on�the book�by�G.� Grossman� and� M.� Kassman� on� Safe Packaging and Load Securing in Transport, who present in their�book�the methods�of�cargo�securing,�including�top‑over� lashing� models� using� fastening� straps�(Grossman��and��Kassman,�2018).�The� specifics� of� oversized� cargo� are� then�
discussed� by� W.� Galor� and� a team� of� authors� in�his book Carriage and Securing of Oversized Cargo in Transport� (Galor et al.,� 2011)� or� in� the paper�(Vrabel et al.,�2018).�Articles�dealing�with�the area�of�cargo�securing�are�usually�focused�on�the issue�of� software� simulations,� e.g.� (Zong et al.,� 2017)�or� (Neumann,� 2015).� The discussion� on� the data�source� for� models� (e.g.� acceleration� coefficients)�appear� rather� sporadically,� e.g.� (Zámečník et al., 2017�or�Jagelčák,�2017).�
MATERIALS AND METHODS
To� obtain� the necessary� data� for� the statistical�analysis,� a transport� experiment� was� conducted�with� the medium� freight� terrain� vehicle� Tatra�810‑V‑1R0R26�13�177�6 × 6.1R� (hereinafter�“T‑810”)�(Kolmaš,�2007)�on�a highway�and�a low‑quality�road�(road�paved�with�granite�blocks)�with�a mileage�of�less�than�45,000 km.�The transport�experiment�was�carried�out�with�the T‑810�without�load.As� a measuring� device� a three‑axis�
accelerometer� with� data� logger� and� OMEGA – – OM‑CP‑ULTRASHOCK‑5� calibration� certificate�with� the measurement� range� ± 5 g� was� used�to� record� the shocks� (acceleration� coefficient�values)�on�each�of�the three�axes�(x – longitudinal,�y – transverse� and� z – vertical)� every� second.�The measuring� device� was� placed� on� the central�steel�frame�of�the vehicle�body.
The measurements were made under optimal climatic� conditions,� the transport� routes� were�
1: Risk Matrix
1018 Martin Vlkovský, Petr Veselík
dry, no precipitation was recorded during the measurements�and�the visibility�was�excellent.�The outdoor� temperature� ranged� from�7� to� 11 °C.�The measurements� were� also� not� influenced� by�traffic�jams�or�slow‑moving�vehicles.�The�first�data�set�(d1)�contains�data�(acceleration�
coefficient� values)� from� the transport� on�the highway�section�Brno – Vyškov,�where�the data�set� consists� of� 3,804� values� (1,268� for� each� axis).�The average� speed� of� transport�was� 76.66� km.h–1.�The second�data� set� (d2)� contains� the acceleration�coefficient� values� collected� on� the road� paved�with�granite�blocks�on�the section�Dědice�(training�area) – Vyškov� and� consists� of� 1,203� values� (401�per�axis).�The average�transport�speed�was�roughly�half�that�of�the first�data�set: 38.60�km.h–1.�The aim�of� the article� is� to� statistically� evaluate� the two�measured� data� sets� (d1 and d2)� and� consequently�compare� them� to� the values� of� normatively�determined�values�of�acceleration�coefficients�and�(theoretical)� values� of� the inertial� forces� obtained�from�the calculations�according�to�the relationships�of�the standard�(EN�12195‑1,�2010).�Before�the statistical�analysis,�normality�tests�were�
performed�using�skewness�and�kurtosis�coefficients�(Johnson� � and� � Wichern,� 1992).� The significance�level� was� α = 0.05.� The data� normality� was� also�verified� using� Q‑Q� plots� and� histograms.� The Q‑Q�plots� were� drawn� for� acceleration� coefficients� in�each� of� the three� axes� (x, y, z).� Although� in� some�data�sets�the distribution�of�acceleration�coefficients�was� not� normal� but� symmetrical� (which� was�verified� by� Q‑Q� plots,� histogram� and� skewness�coefficients)�and� included�outliers,� further�analysis�was� carried� out� assuming� normal� distribution.�When�comparing�two�independent�data�sets�d1 and d2� from� two� normal� distributions,� both� the match�of� variance� (σ1
2 = σ22)� and� the match� of� mean�
values� (µ1 = µ2)�were� tested� (Neubauer et al.,� 2012).�When� testing� the absolute� values� of� mean� values�(arithmetic�means�of�acceleration�coefficient�values�on� individual� axes)� were� used,� i.e.� µ1(abs),� or� µ2(abs) because�of�the value�distribution.�Because�the shocks�
oscillate� around� the value� 0� except� for� the z‑axis�where� the coordinate� axis� is� shifted� by� 1 g� and�the measuring� range� is� limited� by� the measuring�device.�The� comparison� of� the calculated� arithmetic�
means� of� the absolute� acceleration� coefficient�values� and� the inertial� forces�with� the normative�values is also shown graphically taking into account� the value� exceeding� twice� the normative�values – see�Tab. I.Using� the correlation� analysis,� specifically�
the Pearson� correlation� coefficient� (Hendl,�2015),� a statistical� link� between� the acceleration�coefficient�values�and� the resulting� inertial� forces�acting�on�the load�was�found.�The values�of�inertial�forces� (Fx and Fy)� are� calculated� (implicitly)� from�the tensile� strength� requirements� of� the lashing�straps�and�the equality�of�the two�forces:
[ ]µ
µ α
⋅ ⋅ ⋅⋅
⋅ ⋅x z
x s
c – c m gF = n f
2n sinN
( ) [ ]µ
µ α
⋅ ⋅ ⋅⋅
⋅ ⋅x z
x s
c – c m gF = n f
2n sinN
( ),� (1)
[ ]µ
µ α
⋅ ⋅ ⋅⋅
⋅ ⋅
y z
y s
c – c m gF = f
2n sin
( )N ,� (2)
where Fx is longitudinal, Fy transverse inertial force� to� the vehicle� movement,� respectively (see�Fig. 2),� cx, cy, cz� are� the acceleration� coefficients�the individual�axes,�µ�is�the coefficient�of�friction,�m is�the mass�of�the load,�g�is�the gravity�acceleration,�fs is�the coefficient�of�safety�for�frictional�lashing,�n is� the required�number�of� lashing�straps�and�α is the angle�between� the lashing� strap�and� the deck�of�the vehicle.�
RESULTS
It�is�clear�from�the statistical�analysis�of�data�sets�that� the relatively� large� number� of� acceleration�coefficients� exceeded� the normative� values� stated�in� the standard� EN� 12195‑1:2010,� which� are� set�
I: The arithmetic means and medians of the absolute values of the acceleration coefficients for all axes and arithmetic means of inertial values for both datasets (values which exceed normative limits are highlighted in yellow, and the values which exceed normative limits by more than two are highlighted in red)
Acceleration coefficients [–] Inertial forces [N]
Arithmetic mean Median Arithmetic mean
cx cy cz x y z Fxn Fyn Fxi Fyi
d1 0.601 0.640 1.638 0.590 0.610 1.620 30,363 19,820 17,989 12,265
d2 0.916 0.999 2.005 0.860 0.900 1.950 43,441 40,455 17,989 12,265
� Cargo�Securing�–�Comparison�of�Diff�erent�Quality�Roads� 1019
as�follows: 0.8,�0.6�and�1.0�for� the x, y and z�axes,�respectively.� In� data� set� d1,� the normatively� set�limits� were� exceeded� in� 20.61%� of� cases,� and�exceeded� by� a factor� of� two� in� 0.58%� of� cases.�The excess�was�most�common�on�the y‑axis.�In�data�set d2,�the normatively�set�limits�were�exceeded�in�61.68%� of� cases,� by� a factor� of� two� in� 10.72%� of�cases.�Also,�the excess�on�y‑axis�prevailed,�although�the diff�erences�between�axes�were�smaller�than�in�the d1 data�set.�Tab.� I� shows� the results� of� the descriptive�
statistics� for� the absolute� acceleration� coeffi��cient�values,� specifi�cally� the arithmetic� means� and�medians� for� the axes�x, y and z, for both datasets (d1 and d2).� In� addition,� the table also� includes�the results� of� inertial� forces� values,� which� are�essential� for� the choice� of� cargo� securing� system�(not� the value� of� acceleration� coeffi��cients).�The magnitude�of�the inertial�forces�was�calculated�using� formulas� (1)� and� (2)� and� further�normative�limits� (Fxn and Fyn).� Subsequently,� the relevant�values of inertial forces were calculated for both data�sets�(marked�as�Fxi and Fyi�in�Tab. I).�It�can�be�seen�from�Tab. I�that�the lowest�arithmetic�mean�of�the absolute�values�of�the acceleration�coeffi��cients�(0.601)�was�measured�on�the x‑axis�of�the fi�rst�data�set.� Contrarily,� in� the second� data� set,� the highest�arithmetic� mean� of� the absolute� values� of�the acceleration�coeffi��cients�(2.005)�was�measured�on�the z‑axis.�The�descriptive�statistics�presented�in�Tab. I�show�
that�the data�sets�diff�er�greatly.�The average�values�of�the inertial�forces�on�the x‑axis�and�y‑axis�were�exceeded� in� both� data� sets,� in�d2 even more than twice.�In�the second�dataset,�normatively�set�limits�according� to� EN� 12195‑1:2010� were� exceeded� in�fi�ve� cases,� where� the excess� reached� almost� 67%�
for�the y‑axis.�In�contrast,�in�d2,�the excess�occurred�only� in� two� cases� on� the y‑axis� and� the excess�was�relatively�small – less�than�7%.�This�is�mainly�due� to� the relatively� low� normative� values� of�acceleration�coeffi��cients�on�the y‑axis�(cy),�which�is�based� on� greater� risks�when� loosening� the cargo�in�the direction�transverse�to�vehicle�motion.�Both�data� sets� will� be� subjected� to� detailed� statistical�analysis�in�next�part�of�this�article.Because� the measured� data� (the values� of�
acceleration� coeffi��cients)�were� considered� coming�from�normal�distribution�for�all�axes,�a parametric�two‑sample� t‑test�was� used� to� evaluate� both� data�sets.� The test� was� performed� for� all� three� axes�at� a signifi�cance� level� of� α = 0.05.� The results� of�the performed�tests�are�shown�in�Tab. II.�In�the fi�rst�column� of� this� table,� the relevant� acceleration�coeffi��cients� are� listed.� In� the second� column�(AHF),� an alternative� test� hypothesis� of� variance�match� is� shown.� In�column�F,� the test� statistics�of�variance�match�test�is�shown.�In�the fourth�column�the alternative� hypothesis� of�mean� values�match,�and�fi�nally,�the column�denoted�t�contains�the test�statistics� of� a mean� values� match� test� assuming�heteroskedasticity.�The� results� of� the two‑sample� t‑test� shown� in�
Tab. II�show�that�statistically�signifi�cant�diff�erences�exist�between�the two�data�sets�at�the signifi�cance�level α = 0.05� for� the two� tested� statistics.� These�results�point�to�the very�diff�erent�values�of�shocks�generated� on� the highway� (d1)� and� on� the road�paved�with� granite� blocks� (d2)� despite� the almost�halved� average� speed� of� vehicles� on� low‑quality�roads.Subsequent� one‑sided� tests� showed,� at�
the signifi�cance� level� α = 0.05,� that� for� both�monitored�parameters�(arithmetic�mean�of�absolute�
2: Directions of inertial forcesSource: Sdružení�řidičů�CZ,�z.s.,�2019
1020 Martin Vlkovský, Petr Veselík
values� and� variances),� there� is� a statistically�significant� difference� between� both� data� sets� on�all� three� axes� and� for� cx, cy and cz it is valid that the arithmetic�means�of�absolute�values�are�smaller�for d1 than for d2�(µ1 < µ2)�or�the variances�of�values�are smaller for d1 than for d2�(σ1
2 < σ22).
Considering� the laboriousness� of� determining�the inertial�values�especially�for�practice,�the extent�of� correlation� between� acceleration� coefficients� (cx a cy)�and� the relevant� inertial�values� (Fxi and Fyi)� is�further� calculated.� For� the calculation� the Pearson�correlation� coefficient� was� used.� First,� however,�a graphical� comparison� was� made,� the values� of�the inertial� forces� were� plotted� on� the horizontal�axis�and�the corresponding�acceleration�coefficients�were�plotted�on�the vertical�axis.�In�both�cases,�it�was�shown�that�the given�pairs�show�a linear�trend – see�Fig. 3.� Since� the individual� graphs�well� document�the linear�trend,�the statistical�relationship�between�the acceleration� coefficients� and� the resulting�
inertial� forces� acting� upon� the cargo�was� assessed�with� the Pearson�correlation�coefficient�as�well.� Its�values�are�shown�in�Tab. III.Fig. 3� and� the Pearson� correlation� coefficient�
values� in�Tab. III� show�a very�strong�dependence�between� the corresponding� acceleration�coefficients�and�the values�of�inertial�forces�acting�upon�cargo.�The values�of�the Pearson�correlation�coefficient� range� from� 0.990� to� 0.997.� From� such�a strong� dependence� between� the measured�coefficients� and� the calculated� inertial� values,�it� can� be� concluded� that� the results� can� already�be� interpreted� from� the acceleration� coefficient�analysis� (measured� shocks).� Nevertheless,�the analysis� shows� a difference� in� the extent�of� exceeding� the normatively� set� limits� for�the acceleration� coefficient� and� the subsequent�difference� contrary� to� the inertial� forces� by�using� the normatively� determined� acceleration�coefficient�values.�
II: Results of a two‑sample t‑test for all axes
Acceleration coefficients [–] AHF F AHt t
cx σ12 ≠ σ2
2 0.163* µ1 ≠ µ2 –18.406*
cy σ12 ≠ σ2
2 0.256* µ1 ≠ µ2 –15.833*
cz σ12 ≠ σ2
2 0.174* µ1 ≠ µ2 –17.102*
*�indication�of�the values�of�relevant�statistics,�when�the related�null�hypothesis�was�rejected�at�the 5%�significance�level
3: Correlation analysis between cx and Fxi (left figure) and cy and Fyi (right figure)
III: Correlation between acceleration coefficients and the corresponding inertial values
Fx1 Fx2 Fy1 Fy2
cxi 0.995 0.990 – –
cyi – – 0.997 0.994
� Cargo�Securing�–�Comparison�of�Different�Quality�Roads� 1021
DISCUSSION
It� follows� from� the performed� analysis� that�on� the examined� T‑810� vehicle,� the shocks�generated� on� the high‑quality� road� (highway)�and� the lower‑quality� road� (paved�with� granite�blocks)� differ� in� a statistically� significant� way.�On� the basis� of� the one‑sided� test,� it� is� clear�that� the cargo� securing� requirements� will� be�higher in terms of lashing capacity during cargo transport�on�granite‑block‑paved�roads.�It�can�be�assumed� that� the similar� conclusion� will� apply�to�other� types�of�vehicles� too.�The key� impact�of�the results� is� then�on�vehicles�which�operate�on�lower‑quality� roads� (military,� integrated� rescue�system,�farmers,�etc.).The� benefit� may� also� be� seen� in� an� increase�
in� the safety� of� the cargo� securing� during�the transport� of� dangerous� goods,�where� the risk�arising� from� improper�or� insufficient� fastening�of�the load� may� be� significantly� higher.� In� military�conditions,� is�spoken�primarily�of� the transport�of�
ammunition�and� fuel� in�multinational�operations.�In� the case� of� farmers,� transport� of� pressure�cylinders, fuels, pesticides, disinfection chemicals or hazardous waste from agricultural production are� the most� dangerous.� Potential� accidents� can�cause�damage�to�the health�of�persons,�the vehicle�and� other� technical� equipment� and� last� but� not�least�the environment.�Also,� the impact� of� shocks� and� vibrations� onto�
the vehicle�and�driver� is�a relatively� independent�area.� The vehicle� may� experience� faster� wear�due to shocks and vibrations, which can shorten the maintenance� period� or� cause� more� frequent�occurrence of defects, which must be removed at� extra� cost.� The impact� on� drivers� is�mainly� in�the health�area,�where� shocks�and�vibrations� can�cause fatigue, reduced attention span, longer reaction� time� (Buscuházy et al.,� 2016),� impaired�perception� and� reduced� performance� as� a result�of�muscle,� joint,� tendon� and� other� pain� and� thus�negatively�affect�cargo�securing�in�general.
CONCLUSION
Statistical� analysis� of� data� sets� from� the transport� experiment� had� led� to� important� findings�regarding� the existence�of�statistically�significant�differences�between� the measured�values�of�shocks generated on highways and roads paved with granite blocks, which can be considered as third‑class�roads.�This�conclusion�has�impacts�mainly�on�completely�different�requirements�for�cargo�securing�on�roads�of�different�quality�(that�is,�different�classes�of�roads).The� basic� evaluation� of� the measured� values� of� the acceleration� coefficients� show� significant�differences�in�the number�of�exceedances�of�the prescribed�values�during�the given�transports.�On� the highway,� the normatively� set� limits�were� exceeded� in� 20.61%� of� cases,� and� exceeded�by�a factor�of�two�in�0.58%�of�cases.�However,�in�third‑class�road,�normatively�set�limits�were�exceeded� in�61.68%�of�cases,�by�a factor�of� two� in�10.72%�of�cases.�This� implies�much�higher�likelihood� of� emergencies� during� transport� (cargo� release,� accidents,� etc.)� on� the third‑class�road�despite�a significantly� lower�transport�speed.�The results�of� the performed�t‑test� indicate�a statistically�significant�differences�at�a significance�level�α = 0.05�between�the two�types�of�road�surfaces�in�both�monitored�parameters�(arithmetic�means�and�variances).�The�correlation�between�the experimentally�determined�values�of�the acceleration�coefficients�and�the resulting�inertial�forces�is�verified�for�practical�use.�The Pearson�correlation�coefficient�ranges�from�0.990�to�0.997,�indicating�a strong�linear�dependence.�Thus,�from�the experimentally�determined� the acceleration� coefficients� values,� conclusions� can� be�made�without� acceptable�inertial�calculations�with�adequate�accuracy.Changes� in� the Czech� transport� system,� especially� after� 1989,� are� evident.� It� is� not� only�infrastructure,�but�also�means�of�transport�and�increased�transport�capacity.�The poor�condition�of�many�transport�routes�in�the Czech�Republic�can�result�not�only�in�increased�repair�costs�and�shortened�vehicle�life‑cycles�(Binar et al.,�2017),�but�also�in�increased�accident�rates,�which�can�be�discussed�in�an�economic�context�(Vlkovský,�Veselík�and�Grzesica,�2018).�Further�research�will�focus�on�the analysis�of�case�studies�for�other�relevant�vehicle�types�(e.g.�T‑815,�including�container�carriers),�types�of�transport�routes�(road�classes)�or�for�other�modes�of� transport.�The influence�of� shocks�on�cargo�securing�method�or� road�safety�as� such�would�be appropriate to take into account also for transport optimization tasks and models, whether in�military�conditions�(Stodola,�2018)�or�in�other�areas�such�as�agricultural�production�(Kučera�
1022 Martin Vlkovský, Petr Veselík
and�Krejčí,� 2013� or�Košíček et al.,� 2012).� The aim�of� every� transport� is� above� all� to� transport�cargo – that�is,�safely�and�nowadays�it�is�becoming�increasingly�important�at�what�cost.�Damage�to� cargo,� other� technical� equipment,� infrastructure,� environment� or� even� injury� or� death� of�persons� is�a key�issue�which�is�best�dealt�with�by�prevention.�This�means�by�appropriate�and�sufficient�cargo�securing,�including�the proper�training�of�persons�responsible,�especially�loading�teams�and�drivers.
AcknowledgementThe� paper� was� written� with� the support� of� the project� of� long‑term� strategy� of� organization�development: ROZVOLOG: Development�of�Capabilities�and�Sustainability�of�Logistics�Support�(DZRO�ROZVOLOG�2016 – 2020)�funded�by�the Ministry�of�Defence�of�the Czech�Republic.
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Contact informationMartin�Vlkovský:�[email protected]�Veselík:�[email protected]